Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/3626
Title: Random numerical linear precoding and channel estimation in massive MIMO systems
Authors: Mukubwa, Emmanuel Wanyama 
Issue Date: 27-May-2021
Abstract: 
The information growth we have experienced in the immediate past and which continues to
increase has consequently brought about the big data era and when pooled with the vast
increase in subscriber numbers has led to an ever-escalating demand for more efficient and
high-capacity communication systems. The affinity for higher capacity and efficient networks
has necessitated the initiation of wireless fifth generation (5G) networks. Among the key
technologies underlying the wireless 5G network are massive Multiple-Input Multiple-Output
(MIMO) and Cloud Radio Access Network (C-RAN) which enhances spectral efficiency,
energy efficiency, security and robustness but suffers from pilot contamination and fronthaul
finite capacity.
There have been several attempts to minimize pilot contamination in massive MIMO system
through linear precoding. But for those precoding schemes with good performance, they suffer
from intricate problem of matrix inversion owing to large antenna numbers inherent in massive
MIMO system, yet they do not render themselves readily to hardware parallelization. Also,
channel state information estimation remains a challenge within massive MIMO networks.
While the finite fronthaul capacity remains a bottleneck in C-RAN network systems. This study
presents the formulation of iterative linear precoder that is efficiently parallelizable with
efficient channel estimators for massive MIMO and massive MIMO partially centralised CRAN networks.
The channel precoder was formulated and adapted using the iterative linear Rapid Numerical
Algorithm (RNA). This model was then extended to include coordination among multicell
massive MIMO system with receive combining computational complexity and efficiency
evaluation. RNA model is again used to formulate improved linear and semi-blind channel
estimators for massive MIMO systems in combination with the Fast Data Projection Method
(FDPM). The semi-blind channel estimator is combined with compressed data channel
estimator then extended based on Givens transformations and Data Projection Method (DPM)
for massive MIMO partially centralised C-RAN networks. And finally, the estimation of the
signal-to-interference-to-noise ratio, bit error rates, spectral efficiency, energy efficiency and
normalised mean square error for the respective modelled components was realized. The
models above were simulated using MATLAB for the analysis and validation. The TDD downlink massive MIMO system was considered with varying immediate channel
state information qualities for the single cell and multicell systems. For single cell system, there
was optimal performance with regard to the signal-to-interference-to-noise ratio and the bit
error rate when rapid numerical algorithm was used to implement the matrix inversion process
in comparison to existing methods. It also rendered the precoding process highly parallelizable
further reducing the complexity. For instance, for base transceiver station with 128 antennas
serving 32 user terminals at signal-to-interference-to-noise ratio = 20 the average per user
terminal rate was: RNA = 5 bit/sec/Hz, Regularized Zero Forcing (RZF) = 5 bit/sec/Hz and
Truncated polynomial Expansion (TPE at J = 2) = 2.9 bit/sec/Hz. For the case of the Bit Error
Rate (BER), for base transceiver station with 128 antennas serving 32 user terminals at signalto-interference-to-noise ratio = 10 the BER was: RNA = 1, Regularized Zero Forcing (RZF) =
1 and TPE (J = 2) = 5. For the multicell massive MIMO, it was found that the performance of
rapid numerical algorithm implementation gave a good spectral efficiency and energy
efficiency performance in comparison to existing methods while lowering the complexity
further through parallelization. The compressed data channel estimator gave comparable
performance for the spectral efficiency and normalized mean square error when compared to
the improved linear channel estimators. The semi-blind channel estimators for both massive
MIMO and massive MIMO partially centralised C-RAN outperformed the linear channel
estimators as well as the compressed data channel estimator.
These results demonstrate that rapid numerical algorithm can effectively eliminate the intricate
matrix inversion associated with linear precoding while rendering itself to efficient
parallelization. It also shows that the compressed data channel estimator optimally estimates
the channel covariance matrix while reducing the amount of channel state information
transmitted in estimation process. The semi-blind channel estimators have the optimal
performance with regard to the normalised mean square error. It was also illustrated that the
Givens transformation based semi-blind estimator outperforms the FDPM based semi-blind
channel estimator.
Description: 
Thesis presented in fulfilment of the requirements for the degree of Doctor of Engineering in Electronic Engineering in the Faculty of Engineering and the Built Environment at Durban University of Technology, 2021.
URI: https://hdl.handle.net/10321/3626
DOI: https://doi.org/10.51415/10321/3626
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

Files in This Item:
File Description SizeFormat
Mukubwa_2021.pdf4.09 MBAdobe PDFView/Open
Show full item record

Page view(s)

358
checked on Dec 22, 2024

Download(s)

255
checked on Dec 22, 2024

Google ScholarTM

Check

Altmetric

Altmetric


Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.